Electrophilic NF Fluorinating Agents - Chemical Reviews (ACS

Aug 1, 1996 - Matthew D. Walker , F. David Albinson , Hugh F. Clark , Stacy Clark , Nicholas P. Henley , Richard A. J. Horan , Chris W. Jones , Charle...
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Chem. Rev. 1996, 96, 1737−1755

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Electrophilic NF Fluorinating Agents G. Sankar Lal, Guido P. Pez,* and Robert G. Syvret Air Products and Chemicals, Inc., 7201 Hamilton Boulevard, Allentown, Pennsylvania 18195-1501 Received November 20, 1995 (Revised Manuscript Received May 23, 1996)

Contents I. Introduction II. General Preparative Methods III. Survey of NF Reagents A. Neutral Compounds R2NF 1. Sulfonyl Derivatives RSO2N(F)R′ 2. N-Fluoroamines and N-Fluoroamides B. Quaternary (R3N+F A-) Compounds 1. N-Fluoropyridinium Salts 2. Saturated Derivatives C. Nitrogen Fluorides D. Potential Electrophilic NF Compounds IV. Applications in Organic Synthesis A. Synthesis of Fluoroaromatics B. Fluorination of Carbanions 1. Synthesis of R-Fluoro Carbonyl Compounds 2. Synthesis of γ-Fluoro Carbonyl Compounds C. Fluorination of Olefins D. Fluorination of Organometallic Compounds E. Synthesis of (Fluoromethyl)phosphonatess Precursors to Mono- and Difluoroolefins F. R-Fluorination of Sulfides G. Asymmetric Fluorination with NF Reagents V. Reaction Mechanisms and Relative Reactivity A. Concept of Electrophilic Fluorine B. Reaction Mechanisms 1. Electron Transfer Chemistry 2. Reactivity with Organic Nucleophiles C. Relative Reactivity VI. Conclusion

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I. Introduction It is well recognized that the presence of fluorine in medicinals1,2 and plant-protection compounds2-4 can profoundly influence their biological properties. The need for a regioselective formation of carbonfluorine bonds in these and other,5 often complex, organic molecules, has stimulated the development of new synthetic methods that employ a variety of fluorinating agents. These may be classified6 as sources of fluoride ion (F-) or fluorine radicals (F•) and as compounds that can deliver electrophilic fluorine (F+). Most fluorine-containing commodity chemicals and polymers are made starting from hydrogen fluoride or other sources of the fluoride ion.7,8 Examples of * To whom correspondence should be addressed.

such nucleophilic fluorinating agents that are useful for laboratory use or fine chemical synthesis processes are pyridine.HF, Bu4N+ HF2-, activated alkali metal fluorides, etc., and also SF4 and (diethylamino)sulfur trifluoride (DAST), which can convert carbonoxygen to carbon-fluorine bonds.9,10 The fluorination of electron-rich centers, in particular, a direct conversion of C-H to C-F linkages, is usually not feasible with HF-based chemistry; for this radical or electrophilic sources of fluorine are needed. Elemental fluorine can be used for this purpose, but there are significant remaining challenges. At near-ambient temperatures, when acting as a source of F• radicals, it is quite indiscriminate in its chemistry toward organic substrates. However, under carefully regulated conditions fluorine can be a useful synthetic reagent.11,12 An efficient perfluorination of hydrocarbons and some ethers can, for instance, be accomplished by the LaMar and aerosolcontrolled fluorination techniques.13 A regioselective limited introduction of fluorine by direct reaction with the element has in principle been demonstrated for many organic substrates, including carbanions, enolates, olefins, and certain aromatics. Reactions are done with N2-diluted F2, at low temperatures sometimes in the presence of F-F bond-polarizing solvents or reaction modifiers.11-15 Here, the key to selectivity appears to be in using reaction systems where fluorine is delivered in a positive mode, i.e., as an electrophile (F+ source) rather than radical fluorine. Even so, it is in general difficult to achieve high reaction yields in a direct fluorination of organics. An indication of this is that there are few industrial-scale fluorination processes that are based on F2, a notable example being the synthesis of 5-fluorouracil.16 The difficulties associated with direct fluorination have stimulated the development of alternate sources of positive fluorine: electrophilic reagents that can be easily and safely employed in organic syntheses. Perchloryl fluoride, FClO3, xenon difluoride, XeF2, trifluoromethyl hypofluorite, CF3OF, and various acyl and perfluoroacyl hypofluorites, RC(O)OF and RfC(O)OF, were among the first reagent sources of positive fluorine. These compounds display the classical F+ source reactivity as in the addition of fluorine to carbanions and enolates and in the electrophilic fluorination of aromatics.9,17 While FClO3, XeF2, and the hypofluorites are generally more selective electrophilic fluorination reagents than F2, there are limitations that have precluded their widespread use. While perchloryl fluoride has been employed in the industrial scale fluorination of steroid enolates, it has the drawback that with organic compounds it can be a dangerous

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1738 Chemical Reviews, 1996, Vol. 96, No. 5

G. Sankar Lal, a native of Guyana, received the Ph.D. degree in natural products synthesis from the University of New Brunswick, Canada, in 1984. After postdoctoral assignments at Smith Kline Beecham Laboratories and Drexel University, he joined Air Products where he is now a Senior Principal Research Chemist. His work has focused on developing synthetic methodologies for the preparation of fluorine-containing biologically active compounds.

Lal et al.

Robert G. Syvret was born in Canada and in 1987 received the Ph.D degree in main-group fluorine chemistry from McMaster University. In 1987, he joined the Corporate Science Center at Air Products. He is now a Senior Principal Research Chemist in the Company’s Specialty Gas Department where he is continuing with his work in the area of selective fluorination.

Single electron transfer (SET) pathways are also possible (see section V). The NF reagents are generally synthesized by the direct reaction of R2NH and R3N precursors with fluorine. As sources of F+, all behave as oxidizing agents, as most commonly indicated by a usually quantitative conversion of aqueous iodide solutions to iodine. H2O, H+

R3N+F + I- 98 R3NH+ + 1/2 I2 + F- (2)

Guido P. Pez was born in Italy and educated in Australia. He received the Ph.D. degree in inorganic chemistry from Monash University in 1967. After postdoctoral studies at McMaster University, Canada, he joined Allied Signal Corp. and has since 1981 been at Air Products’ Corporate Science Center. He currently holds the position of Chief Scientist with research interests in inorganic and fluorine chemistry, gas separation technologies, and catalysis.

oxidant. Xenon difluoride is a valuable laboratory fluorination reagent but may not be economical for use on a large scale. The hypofluorites are also very powerful oxidizing as well as fluorinating agents. While CF3OF can be stored at room temperature, acetyl and perfluoroacetyl hypofluorites are less stable and are usually generated in situ from their acetate salts and fluorine.18 In recent years, a number of NF fluorinating agents have emerged as generally safer, and easier to handle, selective sources of electrophilic fluorine. These are either neutral, R2NF compounds or quaternary ammonium R3N+F A- salts where A- is a non-nucleophilic anion. Here the R2N- and R3N+organonitrogen fragments are chosen to be good leaving groups, thus promoting a reactivity of the bound fluorine with nucleophiles, as illustrated below for the quaternary salt reagents:

The currently known NF reagents display a wide range of oxidizing and fluorinating power toward nucleophiles. Systems that can be fluorinated include benzene and activated aromatics, stabilized carbanions, activated olefins (aryl-substituted alkenes, alkyl and silyl enol ethers, enol acetates, and enamines), certain organometallics, and aliphatic sulfides. While their reactivity toward these substrates may not be as great as exhibited by XeF2 and some of the in situ prepared hypofluorites, the NF reagents’ ease of use and growing commercial availability has provided the synthetic chemist with a valuable new tool for an efficient selective introduction of fluorine into organic compounds. The preparation, fundamental properties, and reactivity of the N-fluoro electrophilic fluorinating agents are the subject of this review, which is organized as follows. General preparative methods for the neutral R2NF and R3N+F A- salt reagent classes are presented in section II. Then there is a detailed, similarly structured, account of the synthesis and physical and spectroscopic properties of specific NF compounds. Applications of the most common of these reagents in organic synthesis are described in section IV. Finally, unifying concepts on relative fluorination reactivity and reaction mechanisms are discussed. A partial coverage of the chemistry of electrophilic NF compounds may be found in refs 6, 9, 12, 19 and 20.

II. General Preparative Methods The electrophilic NF reagents, for the majority of examples, must be prepared from neat or diluted fluorine, with the only exceptions being a few sub-

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Electrophilic NF Fluorinating Reagents

strates that have been prepared by electrochemical fluorination (ECF),21-23 cobalt trifluoride fluorination,24,25 or transfer fluorination.26,27 For the ternary class of NF reagents (R2NF) there are four distinct preparative methodologies (M-1 to M-4), which are described below. Each method is illustrated here by an example and is referred for the specific reagents that are listed in Table 1. The first of these (M-1) involves fluorination of the parent acid of the desired reagent using elemental fluorine with concomitant formation of HF. This is illustrated by the preparation of DesMarteau’s compound (1a)28-30 (eq 3). 22 °C

(CF3SO2)2NH + F2 9 8 (CF3SO2)2NF + HF 1570 Torr 1a (3) The second method (M-2) involves fluorination of an alkali metal salt of the parent acid with concomitant formation of the NF reagent and an alkali metal fluoride, as in eq 4 for the synthesis of 2a.31

In the next example (M-3) elemental fluorine is not used for the preparation of the NF compound. Instead, electrochemical fluorination (ECF) in anhydrous HF (AHF)21-23 or cobalt trifluoride fluorination24,25 methods lead to the desired reagent. This is illustrated in two parts by eq 5 for the synthesis of perfluoropiperidine 3a.

Chemical Reviews, 1996, Vol. 96, No. 5 1739

M-5 involves fluorination of the parent tertiary amine of the desired reagent using elemental fluorine. This method is illustrated by eq 7 for Banks’ N-fluoroquinuclidinium fluoride (5a).34,35

-

In the next example (M-6), fluorination of an amine precursor, in the presence of an equimolar amount of an alkali metal salt of a weakly nucleophilic anion, leads to the NF reagent and an alkali metal fluoride byproduct. This is illustrated in eq 8 by this synthesis of Umemoto’s N-fluoropyridinium triflate (6a).36-40

In M-7, a Lewis acid, i.e., BF3, adduct of the parent amine of the desired reagent undergoes reaction with elemental fluorine to give the NF cation portion and the corresponding fluoride-Lewis acid anion. This method is illustrated in eq 9 below wherein the preformed boron trifluoride adduct (eq 9a) of pentachloropyridine is fluorinated (eq 9b), resulting in formation of the tetrafluoroborate salt of the desired NF reagent.39

The fourth method (M-4) involves fluorination of a substrate which contains a fluorination facilitating group, i.e., -SiMe3, and is illustrated by eq 6 in the preparation of Purrington’s compound (4).32,33

The quaternary class of electrophilic NF reagents (R3N+F A-) are prepared through the action of either neat or dilute fluorine on an appropriate substrate or by transfer fluorination. The five distinct methods (M-5 to M-9) for the synthesis of this class of compounds are given in the following:

In M-8, a preformed Bronsted acid salt of the parent amine undergoes reaction with elemental fluorine to give the NF compound with concomitant formation of HF as a byproduct. This important preparative sequence for N-fluoropyridinium compounds is illustrated in eq 10a,b by the preparation of N-fluoropentachloropyridinium triflate (6h).39 In M-9, a preformed trimethylsilyl (Me3Si) or dimethylphenylsilyl (PhMe2Si) salt of the parent amine undergoes reaction with elemental fluorine to give the NF compound with liberation of the corresponding fluorosilane as a byproduct. This preparative method is illustrated below in eq 11a,b by the

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Lal et al.

Table 1. Preparation and Physical and Spectroscopic Properties of Selected NF Reagents prep methoda M, solvent, T (°C) (yield, %)b

compd

ref

(CF3SO2NF (1a)

M-1, no solvent, 22 (95%)

28-30

CF3SO2NF

M-2, CH3CN, -35 (89%)

31

M-3, AHF, rt (8-13%)

anal. data avail.c

phys properties

commercial avail.e

i-v

-33.7 (CDCl3)

not currently avail. N/A

ii, v

-24.5 (CDCl3)

N/A

21-23, 92 liquid, bp 49 °C

i-vi

-112.2 (CFCl3)

avail. from FLCHEM

M-4, CFCl3, -78 (63%)

32

waxy white solid, mp 50-53 °C

i-iii, vii

-33 (solvent N/A not specified)

M-5, CFCl3, -35 (86%)

34, 35

hygroscopic white i-iv solid, mp 126-128 °C

M-6, CH3CN, -30 to -35 (88%)

79, 80

cryst white solid, mp 266-268 °C dec

i, ii, iv, v 58.0 (D2O)

avail. from FLCHEM

M-6, CH3CN, -40 (80%)

36-40

cryst white solid, mp 185-187 °C

i, ii, iv, v 48.8 (CD3CN)

avail. from ALD, FLCHEM, PCR

M-6, CH3CN, -40 (89%)

42, 43, 81

cryst white solid, mp 234 °C dec

i, ii, v

49.0 (D2O)

avail. from ALD, APCI, FLCHEM, JANCHIM

M-11, no solvent, 250 (not given)

44, 93

white solid

ii, iii

214.7 (AHF)

N/A

M-1, CFCl3/CHCl3 (1:1), -78 (59%)

46, 48

solid, mp 42-44 °C, bp 90 °C (0.01 Torr)

i-iv

-37.6 (CDCl3)

avail. from ALD, PCR

FN(SO2Ph)2 (10)

M-1, CH3CN, -40 (70%)

51, 54

white solid, mp 114-116 °C

i

FN(SO2CH3)2 (11a)

M-1, CH3CN, -40 (90%)

52

white solid, mp 45-48 °C

i

-37.8 (solvent avail. from not specified) ALD, ALD-SGL, FLCHEM, PCR not reported N/A

M-1, CFCl3/CHCl3 53, 54 (1:1), -40 (>90%)

white cryst solid, mp 139-141 °C with dec

i-v

-12 (C6D6)

M-1, CFCl3/CHCl3 (1:1), -40 (75%)

55, 56

colorless cryst solid, mp 112-114 °C

i, ii

-64.9 (solvent not specified) N/A

M-1, CFCl3/CHCl3 (1:1), -40 (75%)

57, 94

white cryst material, mp 114-116 °C

i, ii, v

9.8 (CDCl3)

N/A

M-1, CFCl3, 0 (76%)

66

not isolated

i

-69.98

(15a)

N/A

69

liquid, bp 37-38 °C (0.15 Torr) liquid, bp 38-39 °C (0.2 Torr)

i-iii

-71.2 (solvent N/A not specified)

(15f)

M-1, H2O, 0-5 (16.5%) or M-1, no solvent, 0-5 (24%)

F – N F – N

(2a)

(3a)

colorless liquid, mp -69.8 °C, bp 90-91 °C vp: 30 Torr (22 °C), 40 Torr (25 °C) pale yellow semisolid when contaminated with 10 mol % NH compd

δ(19F)d of the NF fluorine, ppm (solvent)

F (4) N

O

F (5a) N+

58.6 (D2O)

N/A

F–

F (5c) N+

CF3SO3–

F

(6a) N+

Tf –

F CH2Cl BF4– + N (7a) N+ F

BF4–

NF4+ SbF6- (8a) SO2 F

CH3

N

(9a)

CH3

SO2 NF (12) SO2

(13a)

N/A

NF SO2

NF

(14a)

SO2 O C 18F

N

(CH2)3

O C 19F

N

(CH2)3

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Table 1. (Continued) prep methoda M, solvent, T (°C) (yield, %)b

compd

B2F7– N+

M-7, CH3CN, 0 (33%)

(16)

ref

phys properties

78

tan crystals, mp 196-197 °C

47

the properties of this compd have not yet appeared in the literature liquid, mp -79.9 °C, bp 60.8 °C liquid, bp 62-63 °C (25 Torr)

anal. data avail.c i, ii, v

δ(19F)d of the NF fluorine, ppm (solvent) 48.2 (CH3CN)

N

commercial avail.e avail. from ALD, ALD-SGL, FLCHEM, PCR

F H3C

+ N

+ N F

Tf –

Tf –

(FSO2)2NF (18) (CF2)2 O

C

C N

O

(19a)

(17)

M-1, no solvent, 25 °C modified M-10XeF2 transfer reagent, CF2Cl2, 0-20 (55-65%)

88

modified M-10FClO3 transfer reagent, CCl4, 80% yield.132 This compound has been found to be very useful for introducing the difluoroolefin entity at C2′ of cytidine.133 The (CF3SO2)2NF reagent (1a) also proved quite effective for fluorinating the phosphonate derived ylide. The lithium salt of diethyl (cyanomethyl)phosphonate reacts rapidly to afford the monofluorinated phosphonate in good yields.131 This resulting Horner-Emmons fluorinating reagent is a useful precursor to cyano-substituted vinyl fluoride. Another practical method for the synthesis of vinyl fluorides involves the electrophilic fluorination of vinyl anions.51 Akenyl iodides on lithiation with t-BuLi react with N-tert-butyl-N-fluorobenzenesulfonamide (9h) to prepare alkenyl fluorides.49

F. r-Fluorination of Sulfides The R-fluoro sulfides constitute an important class of fluorinated compounds that has proven to be valuable in modifying the biological activity of β-lactam antibiotics134 and amino acids.135 They also serve as useful synthetic intermediates to medicinally active compounds.136 Various electrochemical processes have been used for R-fluorination of sulfides.137 Electrophilic fluorination of sulfides to produce R-fluoro sulfides has been demonstrated with XeF2138 and with N-fluoropyridinium salts.139 Sulfides bearing R-hydrogens react with N-fluoropyridinium salts (6) in CH2Cl2 at room temperature (NF + e- f >N• + F-

(14)

>N• + e- f >N-

(15)

Interestingly, reduction of the 4-nitro-substituted N-fluorosaccharinsultam 14b takes place by a stepwise process with formation of an intermediate [NF]•radical anion species:

>NF + e- f [>NF]•- f >N• + F -

(16)

The encountered reaction path is a function of both the N-halogen bond dissociation energy and the substrate’s electron affinity. It is proposed that, in general, a concerted simultaneous reduction and cleavage may be expected where the N-halogen bond is relatively weak. On the other hand, when the substrate has a relatively high electron affinity (where there is a low-lying π* orbital for the incoming electron), the stepwise process will be favored. Sultams 14a and 14b have nearly the same NF bond dissociation energy (65 kcal/mol), but the 1.6 eV lower π* level of the nitro compound apparently dictates its reduction by the sequential mechanism (eq 16) where the anion radical appears as an intermediate on the reaction pathway. These electrochemical studies have also furnished some of the first standard potentials for NF compounds: -0.12 V vs SCE for 14a and -0.89 V vs (aqueous) SCE for 14b. Values of redox potentials and intrinsic barriers for electron transfer were used to provide insight on ET transfer vis-a`-vis SN2 fluorination mechanisms as discussed below (section 2b)

2. Reactivity with Organic Nucleophiles In reactions of R2NF and R3N+F A- fluorinating agents with nucleophiles there is characteristically a transfer of charge from these substrates to fluorine, with organofluorine compounds or simply ionic fluoride as potential products. How this transfer takes place, whether by discrete electron transfer (SET) steps, as in the just-described electrochemical processes, or by a direct attack of the nucleophile at fluorine, is an interesting topic for review and discussion. Mechanistic possibilities are represented schematically for the neutral R2NF reagents in Scheme 9. 2a. SET Reactions with Nucleophiles. Umemoto et al.38 explain the observed reactivity of their N-fluoropyridinium (6a-j) salts with anionic and neutral substrates by one-electron transfer (SET) processes involving the F• radical species (Scheme 9). For the anionic substrates they cite as supporting evidence for this mechanism the greater reactivity of the reagents toward Grignards (which are known to undergo SET chemistry) than the organolithiums. Also, there are arguments based on observed product distributions. For olefin and aromatic substrates it is proposed that the electron transfer takes place

through the initial formation of a (charge-transfer) π complex. DesMarteau et al.117 propose a similar SET mechanism for fluorinations by N-fluoro-perfluoroalkylsulfonimides 1a-f. They also cite the formation of sometimes highly colored charge-transfer complexes, which could be intermediates to products that contain some, or even no, fluorine. A localized SET transfer process has been invoked to explain the ortho-directed fluorination of N,N-dimethylaniline by perfluoropiperidine (3a).155 Kochi et al.156-158 have established an interesting and particularly revealing link between the mechanisms of electrophilic aromatic nitration and fluorination with, respectively, N-nitropyridium (O2NPy+) and N-fluoropyridium cations. Nitration of aromatics156 with the former was shown to take place via a multistep pathway involving the rapid initial formation of charge-transfer (CT) or electron donoracceptor (EDA) complexes (eq 17). KEDA

ArH + O2NPy+ {\} [ArH, O2NPy+]

(17)

EDA complexes display characteristic chargetransfer (CT) absorption bands in the UV/vis region, which in this case correspond to the following transition, eq 18. hνCT

[ArH + O2NPy+] 98 [ArH•+, PyNO2•] (18) There is a strong correlation between the activation energy for nitration and this electronic excitation energy hνCT, which, in turn, is a function of the HOMO-LUMO gap between the aromatic donor and acceptor electrophilic cation. The activation process of eq 18 occurs thermally, as in conventional nitration, or where it is stimulated in photolytic reactions by irradiation at the CT band energy (hνCT). In both instances, the [ArH•+, PyNO2•]-activated complex is transformed in several steps into the [HAr+NO2] classical Wheland intermediate that leads to the final nitration product. Related, though much less extensive, studies by Kochi et al.157, 158 point to the occurrence of similar mechanisms in the electrophilic fluorination of aromatics by N-fluoropyridinium salts. N-Fluoro-3,5dichloropyridinium triflate was shown to interact with a series of aromatic donor substrates forming EDA complexes with characteristic CT absorption bands. A correlation was established between this CT energy (hνCT) and the ionization potential (Ip) of the aromatic donors, as was done for nitration. With a progressive decrease in Ip, hνCT correspondingly

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Electrophilic NF Fluorinating Reagents

Chemical Reviews, 1996, Vol. 96, No. 5 1751

Scheme 10

Scheme 11

N2

diminishes, making the excited charge-transfer state [ArH•+, FPy•] more accessible and the substrate thus potentially more reactive to electrophilic fluorination. The aromatics of listed Ip values (eV), durene (8.05), 1-methoxynaphthalene (7.72), anthracene (7.55), 2,6dimethoxynaphthalene (7.58), and 9-methylanthracene (7.31), all form colored CT complexes with the fluorinating reagent, but only for the last two, more electron-rich substrates, was the color slowly bleached on standing (in the dark). However, all were fluorinated under photolysis by irradiating at the CT energy. Remarkably, the thermal and photolytic charge-transfer fluorination of the noted two substrates gave essentially the same product distribution. In both cases, for 2,6-dimethoxynaphthalene only the 1-fluoro derivative was obtained, while 9-methylanthracene gave 9-fluoro-10-methylanthracene and coupling products of the intermediate benzyl radical (see Scheme 10). These results (which are similar to findings with nitration) point to a close relationship between the activated complex in the thermal fluorination process and the ion-radical pair, i.e., [ArH•+, FPy•] in the charge-transfer photochemical synthesis.158 2b. Nucleophilic Displacement at Fluorine. As illustrated in Scheme 9, this is the classical SN2 reaction mechanism. Attack on fluorine by the nucleophile results in the displacement of the R2Ngroup, which must necessarily be a better leaving group than fluoride.17 In recent terminology, this may be viewed as a “fluorophilic” reaction.159 It is the mechanism first invoked in the present context by Banks and Williamson60 to explain the fluorination of some carbanions by perfluoropiperidine (3a). It was subsequently invoked by Barton160 to explain the fluorination of activated olefins by CF3OF and has remained an alternative to the discussed SET formalism. Differding et al.161,162 in conjunction with Saveant, Andrieux, and co-workers,154 have provided the most incisive analysis of this question of nucleophilic substitution versus electron transfer in electrophilic fluorination. Experiments with a radical clock fluo-

rination substrate and kinetic studies in the context of ET theory predictions appear to rule out radical pathways, thus pointing to the operation of an SN2 mechanism, at least for the investigated reagent/ substrate combinations. The general concept of using a radical clock as a mechanistic probe is illustrated with reference to Scheme 11. The fluorination substrate is a carbanion containing a 5-hexenyl carbon chain, which if oxidized to a radical in the fluorination process should cyclize to a cyclopentylmethyl radical intermediate. Reaction of a specific citronellic ester enolate probe of this kind with the three NF reagents 14a, 10, and 5c resulted only in fluorination at the carbanionic carbon of the enolate; no cyclic products were detected. While the use of xenon difluoride leads to the same fluorinated compounds, a cyclic non-fluorinated product is also formed. This indicates that free radicals are not intermediates in the fluorination path, but may be involved, as with XeF2, in side reactions to give nonfluorinated compounds. The fluorination of this model enolate is thus most simply accounted for by an SN2 mechanism, with ET as a potential competitive but “unproductive” process as seen in the reaction with XeF2. It is noted, however, that these results do not exclude the possibility of electron transfer, i.e., (>NF, Nu-) to (>NF•-, Nu•) followed by a very fast recombination within a solvent cage to fluorinated products, but merely fix a lower limit to the rate constant for this process. Further insight into the problem of nucleophilic substitution versus electron transfer was obtained from a comparison between observed rate constants for electrophilic fluorination and calculated rates from ET theory.154,162 Rate constants were measured for reactions of N-fluorosultam 14a with a series of nucleophiles of known redox properties. The rate calculation for dissociative electron transfer requires a knowledge of the standard redox potentials (E°) and the Marcus reorganization energies of the two reactive partners. The standard potential, E° for 14a

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1752 Chemical Reviews, 1996, Vol. 96, No. 5 Table 2. Reaction of N-Fluorosultam 14a with Nucleophiles: Comparison between Predicted154 Dissociative Electron Transfer Rate Constants kDET and Experimental169 kEXP Rate Constants

Lal et al.

instead radical coupling products (Schemes 10 and 11) or total charge-transfer as in the formation of the N,N,N′,N′-tetramethyl-1,4-phenylenediamine radical cation (Table 2). Also, it should be noted that the mechanistic studies were done on quite different NF reagent/substrate systems: cationic N-fluoropyridinium and neutral N-fluorosultam reagents, employing, respectively, aromatic and carbanionic-type substrates. Perhaps as mechanistic studies are extended to a greater reactivity range of reagents and nucleophiles a more unified mechanistic view of electrophilic fluorination will emerge.

C. Relative Reactivity

* From ref 162, calculated using an estimated E° for 14a of -0.67 V vs SCE; other kDET values in this table were apparently arrived at154 using the electrochemically derived E° for 14a -0.12 V vs SCE.

(-0.12 V vs SCE), was derived from the electrochemical R2NF reduction studies described154 earlier in this review (section V.B.1). Results are summarized in Table 2 where for the listed nucleophiles computed dissociative electron-transfer rate constants154 are compared with experimental rate data and fluorination yields.162 For the first three substrate nucleophiles, the observed rates are from 11 to 13 orders of magnitude faster than would be expected from a dissociative ET pathway. Electron transfer is too slow to account for the observed fluorination rates, and a nucleophilic attack on fluorine is therefore invoked. The apparent decrease in fluorination yield for the last two substrates is ascribed to the occurrence of competing ET reactions that do not lead to fluorinated products. The extreme case of this is the dissociative electron transfer reaction of 14a with N,N,N′,N′-tetramethyl-1,4-phenylenediamine, which yields only the aromatic radical cation and fluoride. It is clear in reviewing this section that there is currently no single widely-accepted mechanism for electrophilic fluorination. There is the view of an initial charge-transfer complex that undergoes electron and fluorine radical transfer steps as postulated by Umemoto and DesMarteau and substantiated by Kochi’s studies in the broader context of electrophilic aromatic substitution. On the other hand, evidence presented by Differding, Saveant et al. seems to rule out (with certain caveats) an ET pathway for fluorination of their substrates, and an SN2 displacement on fluorine is, therefore, invoked as the most likely mechanism. However, there is common ground. There seems to be agreement that there can be ET processes that do not lead to fluorination, but yield

The NF compounds described in section III display a very wide range of chemical reactivity as sources of electrophilic fluorine or simply as oxidants. Demonstrably, the most powerful are the NF4+ salts, which even fluorinate nitrobenzene97 and methane163 by apparently electrophilic mechanisms. Further down on a purely qualitative reactivity scale is (CF3SO2)2NF (1a), which at room temperature readily fluorinates benzene, but not chlorobenzene.28 Then there are a number of NF reagents, cationic and neutral of greatly varying fluorinating power. Of these it is the R3N+F A- salts that are usually the more reactive. Thus, N-fluoropentachloropyridinium triflate (6h) in CH2Cl2 fluorinates benzene at reflux38 and may be comparable in reactivity to 1a. The Selectfluor reagent 7a in CH3CN reacts with toluene at 80 °C to give 2- and 4-fluorotoluenes.41 Neutral reagents such as the N-fluorosulfonimides 10 and 12 react only with more activated aromatics.54 At the other extreme are the N-alkyl-N-fluoro-p-toluenesulfonamides 9a-p, which apparently, will only react with appropriate aromatic carbanion substrates.46 There have been only limited attempts to quantitatively rank electrophilic fluorination agents in terms of relative reactivity and overall usefulness. Christe and Dixon,164 on the basis of quantummechanical calculations, developed a scale of F+ detachment energies for a series of XFn+, so-called oxidative fluorinators. Values of these energies (in kcal mol), with respect to F+ set at zero, for KrF+ (for reference) and the cited NF compounds are KrF+ (115.9), N2F+ (139.3), NF2O+ (175.3), and NF4+ (180.1), which correspond in this series to an increasing thermodynamic stability of the N-fluorocation. It would clearly be of interest to extend these calculations to the other R3N+F cationic reagents that have been described in this review. A fundamental quantity that should provide an indication of the relative reactivity of NF reagents is their electrochemical standard potential, E°. Unfortunately, reduction of these species at electrodes is in most cases irreversible, and only data on peak potentials (Ep) usually observed at a considerably negative overvoltage58 are available.165 Such data (at specified experimental conditions) have nevertheless proved useful in providing some measure of the relative reactivity of NF reagents. Peak reduction potentials for 10 NF fluorinating agents measured in CH3CN at a Pt electrode were used as a basis for a relative reactivity scale.41 A listing of compounds of decreasing Ep values corre-

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Electrophilic NF Fluorinating Reagents

sponding to an expected diminishing electrophilic fluorination reactivity was provided. The ordering from (CF3SO2)2NF (1a) (Ep ) 0.18V vs SCE) to the least reactive N-fluorosulfonamide, H3C(C6H4)SO2N(C3H7)F (Ep ) -2.20V vs SCE) was shown to be consistent with available qualitative reactivity data on the fluorination of model aromatic substrates. Electrochemical reduction data for N-fluorosultam, N-fluorosulfonamide reagents, the ring-substituted N-fluoropyridium, and N-fluoroquinuclidinium salts was provided by Differding et al.58 Because different experimental conditions were employed, a detailed comparison of this data with peak potentials from ref 41 is not possible. There are, however, similar trends as in the very significant changes in Ep (and reactivity) with different substituents of the nitrogen atom. Sudlow and Woolf166 have criticized the ordering of chemical reactivity from electrochemical measurements, citing specifically ref 41. Principal reasons given relate to claimed uncertainties in the measurement and interpretation of Ep values, issues which were addressed in this work and are noted above. As an alternative, they have described an approach that is based solely on data from semiempirical molecular orbital calculations and is illustrated as follows. For a series of R3N+F reagents and R3N precursors the calculated enthalpy of the “reduction couple” represented here by [∆Hf°(R3N) - ∆Hf°(R3N+F)]167 was correlated with the LUMO energy of the R3N+F cation. A (surprisingly) linear relationship between these two quantities was noted for the N-fluoropyridium cation and several ring-substituted analogs. The result is said to be consistent with these reagents’ relative reactivity, with low LUMO energies and more negative “reduction couples” corresponding to greater fluorinating power. However, the correlation did not extend to R3Nd piperidine, quinuclidine, N2, and FCN systems. It is concluded that by this computational approach an adequate ordering in fluorination reactivity can only be obtained for a closely related set of reagents. Reports of similar molecular orbital calculations on N-fluoropyridinium reagents have appeared.168 More recently, Solkan et al.,169 also using semiempirical molecular orbital methods, calculated the formation enthalpies of a number of ring-substituted N-fluoropyridinium reagents both under gas phase conditions and in the presence of a (hypothetical) polar solvent. As expected, the largest enthalpy changes in passing from the gas phase to solution are seen for N-fluoropyridinium salts containing charged ring substituents. In fact, solution and ionpairing effects can greatly influence fluorination reactivity.38 Thus, N-fluoropyridinium triflate reacts readily with a model silyl enol ether in methylene chloride; the reaction is slower in CH3CN but does not proceed at all in THF. In this system triflate is generally a more effective counteranion than BF4-, SbF6-, etc. This is ascribed to a greater solubility of its salts in low polarity solvents and a lesser tendency to ion pair, thus maintaining the effective positive charge on the N-fluoro nitrogen atom.38 There have been attempts to correlate NF, 19F chemical shifts with fluorinating power as was done for fluoroxy compounds.170 For N-fluoropyridinium

Chemical Reviews, 1996, Vol. 96, No. 5 1753

salts171 the 19F resonance shifts downfield with substitution by increasingly electron-withdrawing groups at the β and γ positions on the ring. This correlates with the pKa values of the corresponding pyridines and is consistent with the notion that electrophilic fluorination reactivity is a function of the electron density on nitrogen. For substituents at the R positions, however, there are no clear trends between the 19F shift and reactivity, but there is still a correlation with the pKa’s of the corresponding substituted pyridines.

VI. Conclusion The clearly exhibitedseven if not well understoods electrophilic fluorinating behavior of the described NF compounds, the hypofluorites, xenon difluoride, etc., is a manifestation of the extreme electronegative character of fluorine. Reagents of the NF class, several of which are now commercially available, provide the organic chemist with a relatively safe and practical means of selectively positioning fluorine at chosen carbanionic-type sites in molecules. However, the reagents’ stability in storage and ease of use are achieved at the cost of employing an R2N- or R3N+organic carrier. For many large-scale uses elemental fluorine, somehow “tamed” to act as a predictablyselective electrophile, would ultimately be the most economical and environmentally “greener” alternative.

Acknowledgments We are grateful to A. Gilicinski, H. Cheng, and W. Casteel for helpful discussions and to R. Calse for the preparation of this manuscript.

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